PHAGE EMPTY SET-29 PROTEIN P6 IS IN A MONOMER-DIMER EQUILIBRIUM THAT SHIFTS TO HIGHER ASSOCIATION STATES AT THE MILLIMOLAR CONCENTRATIONS FOUND IN-VIVO
Am. Abril et al., PHAGE EMPTY SET-29 PROTEIN P6 IS IN A MONOMER-DIMER EQUILIBRIUM THAT SHIFTS TO HIGHER ASSOCIATION STATES AT THE MILLIMOLAR CONCENTRATIONS FOUND IN-VIVO, Biochemistry, 36(39), 1997, pp. 11901-11908
Protein p6 from Bacillus subtilis phage empty set29 (M-r = 11 800) bin
ds in vitro to DNA forming a large nucleoprotein complex in which the
:DNA wraps a multimeric protein core. The high intracellular abundance
of protein p6 together with its ability to bind the whole empty set29
DNA in vitro strongly suggests that it plays a role in viral genome o
rganization. We have determined by sedimentation equilibrium analysis
that protein p6 (1-100 mu M range), in the absence of DNA, is in a mon
omer-dimer equilibrium, with an association constant (K-2) of similar
to 2 x 10(5) M-1. The intracellular concentration of protein p6 (simil
ar to 1 mM) was estimated measuring the number of copies per cell (7 x
10(5)) and the cell volume (1 x 10(-15) L), At concentrations around
1 mM, protein p6 associates into oligomers. This self-association beha
vior is compatible with a dimer-hexamer model (K-2,K-6 = 3.2 x 10(8) M
-2) or with an isodesmic association of the dimer (K = 950 M-1), becau
se the apparent weight-average molecular mass (M-w,M-a) does not reach
saturation at the highest protein concentrations. The sedimentation c
oefficients of protein p6 monomer and dimer were 1.4 and 2.0, respecti
vely, compatible with translational frictional ratios (f/f(0)) of 1.15
and 1.30, which slightly deviate from the hydrodynamics of a rigid gl
obular protein. Taking together these results and considering the stru
cture of the nucleoprotein complex, we speculate that the observed oli
gomers of protein p6 could mimic a scaffold on which DNA folds to form
the nucleoprotein complex in vivo.